Recording method, recording apparatus, and signal processing circuit for recording information on optical recording medium

ABSTRACT

In a recording method or apparatus, in order to set an optimal recording condition by a minimal number of times of testing, test recording is carried out while changing power and pulse width of recording pulses in a stepwise manner. Conditions for the test recording are concentrated in a region of a matrix defined by power×pulse width.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.11/026,613 filed on Dec. 30, 2004, which is incorporated by referencehereby in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a method and an apparatus for recordinginformation onto an optical recording medium such as an optical disk.More specifically, the present invention relates to a method and anapparatus that are effective to set an optimal recording condition by asmaller number of times of test recording for determining a recordingcondition.

2. Description of the Related Art

When information is recorded on an optical recording medium such as aCD-R or a DVD-R, matching between a medium on which information is to berecorded and a recording apparatus (hereinafter referred to as a drive)used for recording depends on individual combination. This is due tofactors relating to the medium, such as variation in optimal recordingcondition due to difference in the type of recording material of themedium or due to variation that occurs in film formation duringmanufacturing, and due to factors relating to the drive, such asvariation in optimal recording condition due to variation that occurs inassembly during manufacturing or due to difference in the type of pickupor semiconductor laser included in the drive. Actually, a recordingcondition that is suitable for each combination of a medium and a driveis determined by a combination of these factors.

Thus, according to a conventional method, test recording is carried outusing a combination of medium and drive that is actually used forrecording, and a recording condition with which most favorable recordingquality is achieved is selected.

Recording condition is mainly controlled based on the power of laserwith which a medium is irradiated (hereinafter referred to as power) andthe width of recording pulses (hereinafter referred to as pulse width).Thus, in order to find an accurate optimal condition, it is ideal totest all the combinations of power and pulse width. However, a testrecording area provided on a medium is restricted and increase in thenumber of times of testing affects a size of area to be used by a useror the number of additional recording operation available. Thus, it isdesired to find an optimal recording condition by a minimum number oftimes of testing.

Thus, conventionally, ID information that allows a drive to identify thetype of medium is stored in the medium itself, and test conditionsprepared in advance for individual media types are stored in the drive.When information is actually recorded, ID information of a medium loadedonto the drive is read from the medium, and a test condition associatedwith the ID information is used.

FIG. 31 is a schematic diagram showing features of a method fordetermining a test condition based on ID information stored on a medium.As shown in FIG. 31, in which a range of test condition is expressed bya matrix image of a combination of power and pulse width of recordingpulse 10, the method uses test conditions in which the power is changedgradually while the pulse width is fixed.

FIG. 32 is a schematic diagram showing playback characteristics obtainedby the conventional method shown in FIG. 31. As shown in FIG. 32, whenpower is changed by the conventional method shown in FIG. 31, playbackcharacteristics to be obtained, such as jitter values, are representedby a characteristics curve having a pole at a certain power value, andthe minimum value is selected as an optimal recording condition. Thismethod is most generally used to determine a test condition, andimprovements of this method have been proposed as described below.

FIG. 33 is a schematic diagram showing features of a method disclosed inJapanese Patent No. 3024282. As shown in FIG. 33, according to themethod, a range for changing power is restricted based on a temperatureof an optical disk, or based on information regarding an optimalrecording condition, that are recorded in advance on an optical disk.This method is effective to reduce the number of times of testing.

According to the method, however, matching between an optical disk onwhich information is to be recorded and a drive used for recording isnot actually examined. Since information that serves as a basis forrestricting test range is estimated information such as temperature, theprobability that an optimal condition exists in the restricted testrange is low, so that the method is not sufficient to find an optimalcondition by a small number of times of testing. Furthermore, similarlyto the conventional method described earlier, an optimal condition couldbe missed because it is a method in which only the power is changed.

FIG. 34 is a schematic diagram showing features of methods disclosed inJapanese Unexamined Patent Application Publications No. 2000-36115, No.2000-182244, and No. 2003-203343. These methods focus on changing pulsewidth, and pulse width is changed while the power is fixed.

According to these methods, however, since pulse width is changed withina wide range, the number of times of testing is not sufficientlyreduced. Furthermore, since test recording is carried out with the powerfixed, the methods are not sufficient to find an optimal condition.

As a method effective to reduce testing time, paragraph [0030] ofJapanese Patent No. 3024282 describes “ . . . with the sameconfiguration shown in FIG. 1, it is possible to use a wide range oftest conditions for the first test recording and determine an optimalrecording condition with a low precision, and then determine an optimalrecording condition at a higher precision at each time of test recordinguntil desired recording quality is obtained or an optimal recordingcondition of a desired precision is found. This is effective to reducethe length of time needed to find an optimal recoding condition whenoptimal recording condition considerably varies depending on combinationof optical disk recording apparatus and optical disk, and optimalrecording condition must be determined at a high precision.” Thismethod, however, only repeats testing at different precisions. Thus,unless playback quality is checked at the first time of test recording,the number of times of testing is not sufficiently reduced even ifplayback quality is tested at the second time of testing.

SUMMARY OF THE INVENTION

In view of the situation described above, it is an object of the presentinvention to provide a recording method and a recording apparatus thatare effective to set an optimal recording condition by a small number oftimes of test recording.

In order to achieve the object, according to an aspect of the presentinvention, a recording method for recording information onto an opticalrecording medium with a recording condition determined based on a resultof test recording carried out by irradiating the optical recordingmedium with pulses of laser beams is provided. The test recording iscarried out while changing a power of the laser beams in a stepwisemanner, and a range of changing the power is determined based on aresult of checking recording characteristics prior to the testrecording.

The test recording may be carried out while changing a pulse width in astepwise manner and changing the power in a stepwise manner for eachvalue of the pulse width changed.

The recording characteristics may be checked by carrying out testrecording on the optical recording medium with a plurality ofpredetermined reference conditions and detecting a result of reproducedcharacteristics.

The range of changing the power may be determined based on a differencebetween a larger power value and a smaller power value at two pointsthat satisfy a playback criterion. The larger and smaller power valuesbeing derived based on results of approximating the recordingcharacteristics of the optical recording medium using a plurality ofplayback values obtained by detecting the playback characteristics.

The range of changing the power may be determined based on a differencebetween a larger power value and a smaller power value at two pointsthat are most approximate to a playback criterion among a plurality ofplayback values obtained by detecting the playback characteristics.

The range of changing the power may be set based on a power value at apole of change in the playback characteristics.

According to another aspect of the present invention, a recording methodfor recording information onto an optical recording medium with arecording condition determined based on a result of test recordingcarried out by irradiating the optical recording medium with pulses oflaser beams is provided. The test recording is carried out whilechanging a pulse width in a stepwise manner, and a range of changing thepulse width is determined based on a result of checking recordingcharacteristics prior to the test recording.

The test recording may be carried out while changing a power of thelaser beams in a stepwise manner and changing the pulse width in astepwise manner for each value of the power changed.

According to another aspect of the present invention, a recordingapparatus for recording information onto an optical recording mediumwith a recording condition determined based on a result of testrecording carried out by irradiating the optical recording medium withpulses of laser beams is provided. The test recording is carried outwhile changing a power of the laser beams in a stepwise manner, and arange of changing the power is determined based on a result of checkingrecording characteristics prior to the test recording.

According to another aspect of the present invention, a recordingapparatus for recording information onto an optical recording mediumwith a recording condition determined based on a result of testrecording carried out by irradiating the optical recording medium withpulses of laser beams is provided. The test recording is carried outwhile changing a pulse width in a stepwise manner, and a range ofchanging the pulse width is determined based on a result of checkingrecording characteristics prior to the test recording.

According to another aspect of the present invention, a signalprocessing circuit that is to be included in a recording apparatus forrecording information onto an optical recording medium with a recordingcondition determined based on a result of test recording carried out byirradiating the optical recording medium with pulses of laser beams isprovided. The signal processing circuit includes a section for carryingout test recording while changing a power of the laser beams in astepwise manner; and a section for determining a range of changing thepower based on a result of checking recording characteristics prior tothe test recording.

According to another aspect of the present invention, a signalprocessing circuit that is to be included in a recording apparatus forrecording information onto an optical recording medium with a recordingcondition determined based on a result of test recording carried out byirradiating the optical recording medium with pulses of laser beams isprovided. The signal processing circuit includes a section for carryingout test recording while changing a pulse width in a stepwise manner;and a section for determining a range of changing the pulse width basedon a result of checking recording characteristics prior to the testrecording.

According to another aspect of the present invention, a recording methodfor recording information onto an optical recording medium with arecording condition determined based on a result of test recordingcarried out by irradiating the optical recording medium with pulses oflaser beams is provided. The recording method includes the step ofchecking recording characteristics prior to the test recording. Thenumber of times of recording during the test recording is changed basedon a result of checking the recording characteristics.

The change in the number of times of recording may involve a change in apower condition of the laser beams and/or a change in a pulse condition.

The recording characteristics may be checked by irradiating the opticalrecording medium with pulses of laser beams by at least two sets ofrecording condition that differ in a power condition of the laser beamsand/or a pulse condition.

According to another aspect of the present invention, a recording methodfor recording information onto an optical recording medium with arecording condition determined based on a result of test recordingcarried out by irradiating the optical recording medium with pulses oflaser beams is provided. The test recording is carried out whilechanging a power of the laser beams in a stepwise manner, and the numberof times the power is changed is determined based on a result ofchecking recording characteristics prior to the test recording.

The test recording may be carried out while changing a pulse width in astepwise manner and changing the power in a stepwise manner for eachvalue of the pulse width changed.

The recording characteristics may be determined by carrying out testrecording on the optical recording medium by a plurality ofpredetermined recording conditions and detecting a result of reproducedcharacteristics.

The number of times the power is changed may be determined based on adifference between a larger power value and a smaller power value at twopoints that satisfy a playback criterion. The larger and smaller powervalues are derived based on results of approximating the recordingcharacteristics of the optical recording medium using a plurality ofplayback values obtained by detecting the playback characteristics.

The number of times the power is changed may be determined based onrelationship between a playback criterion and results of approximatingthe recording characteristics of the optical recording medium using aplurality of playback values obtained by detecting the playbackcharacteristics.

The number of times the power is changed may be determined based on adifference between a larger power value and a smaller power value at twopoints that are most approximate to a playback criterion among aplurality of playback values obtained by detecting the playbackcharacteristics.

The number of times the power is changed may be determined based onrelationship between a playback criterion and two points that are mostapproximate to the playback criterion among a plurality of playbackvalues obtained by detecting the playback characteristics.

A range of changing the power may be set based on a power value at apole of change in the playback characteristics.

The number of times the power is changed may be determined based onrelationship between a predetermined playback criterion and a pluralityof playback values obtained by detecting the playback characteristics,and the number of times is changed by additional recording with arecording condition that is different from a recording condition used tocheck the recording characteristics.

According to another aspect of the present invention, a recording methodfor recording information onto an optical recording medium with arecording condition determined based on a result of test recordingcarried out by irradiating the optical recording medium with pulses oflaser beams is provided. The test recording is carried out whilechanging a pulse width in a stepwise manner, and the number of times thepulse width is changed is determined based on a result of checkingrecording characteristics prior to the test recording.

The test recording may be carried out while changing a power of thelaser beams in a stepwise manner and changing the pulse width in astepwise manner for each value of the power changed.

According to another aspect of the present invention, a recordingapparatus for recording information onto an optical recording mediumwith a recording condition determined based on a result of testrecording carried out by irradiating the optical recording medium withpulses of laser beams is provided. The test recording is carried outwhile changing a power of the laser beams in a stepwise manner, and thenumber of times the power is changed is determined based on a result ofchecking recording characteristics prior to the test recording.

According to another aspect of the present invention, a recordingapparatus for recording information onto an optical recording mediumwith a recording condition determined based on a result of testrecording carried out by irradiating the optical recording medium withpulses of laser beams is provided. The test recording is carried outwhile changing a pulse width in a stepwise manner, and the number oftimes the pulse width is changed is determined based on a result ofchecking recording characteristics prior to the test recording.

According to another aspect of the present invention, a signalprocessing circuit that is to be included in a recording apparatus forrecording information onto an optical recording medium with a recordingcondition determined based on a result of test recording carried out byirradiating the optical recording medium with pulses of laser beams isprovided. The signal processing circuit includes a section for carryingout test recording while changing a power of the laser beams in astepwise manner; and a section for determining the number of times thepower is changed, based on a result of checking recordingcharacteristics prior to the test recording.

According to another aspect of the present invention, a signalprocessing circuit that is to be included in a recording apparatus forrecording information onto an optical recording medium with a recordingcondition determined based on a result of test recording carried out byirradiating the optical recording medium with pulses of laser beams isprovided. The signal processing circuit includes a section for carryingout test recording while changing a pulse width in a stepwise manner;and a section for determining the number of times the pulse width ischanged, based on a result of checking recording characteristics priorto the test recording.

As described above, according to the present invention, a condition fortest recording is determined based on a result of checking recordingcharacteristics prior to the test recording. Thus, it is possible tofind, by a smaller number of times of testing, a recording conditionsuitable for a combination of medium and drive that are actually used.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram showing features of test conditionsaccording to an embodiment of the present invention.

FIG. 2 is a diagram showing jitter characteristics in relation to changein power and pulse width.

FIG. 3 is a block diagram showing an optical information recordingmedium and the overall construction of an optical information recordingapparatus according to an embodiment of the present invention.

FIG. 4 is a flowchart showing a procedure that is executed by a driveaccording to the embodiment.

FIG. 5 is a flowchart showing details of a step of determining areference threshold, shown in FIG. 4.

FIG. 6 is a schematic diagram showing an example relating to the flowshown in FIG. 5.

FIG. 7 is a schematic diagram showing an example relating to the flowshown in FIG. 5.

FIGS. 8A and 8B are schematic diagrams showing examples where valleypatterns are obtained as results of testing recording characteristics instep S20 shown in FIG. 4.

FIGS. 9A and 9B are schematic diagrams showing examples whereright-decreasing patterns are obtained as results of testing recordingcharacteristics in step S20 shown in FIG. 4.

FIGS. 10A and 10B are schematic diagrams showing examples whereright-increasing patterns are obtained as results of testing recordingcharacteristics in step S20 shown in FIG. 4.

FIG. 11 is a schematic diagram showing an example of determining a testregion in step S22 shown in FIG. 4 when a valley pattern is obtained instep S20.

FIG. 12 is a schematic diagram showing an example of determining a testregion in step S22 shown in FIG. 4 when a right-decreasing pattern isobtained in step S20.

FIG. 13 is a schematic diagram showing an example of determining a testregion in step S22 shown in FIG. 4 when a right-increasing pattern isobtained in step S20.

FIG. 14 is a table showing an example where eight patterns are used instep S20 shown in FIG. 4.

FIG. 15 is a schematic diagram showing an example method of obtaining apower range used in step S22 shown in FIG. 4 by curve approximation.

FIG. 16 is a schematic diagram showing another example method ofobtaining a power range used in step S22 shown in FIG. 4 by curveapproximation.

FIG. 17 is a schematic diagram showing an example where a power rangeused in step S22 shown in FIG. 4 is determined by sampling.

FIGS. 18A and 18B are schematic diagrams showing examples of pulsepatterns used in test recording in step S24 shown in FIG. 4.

FIGS. 19A and 19B are schematic diagrams showing examples of otherfactors to be adjusted, determined in step S26 shown in FIG. 4.

FIGS. 20A and 20B are schematic diagrams showing examples of otherfactors to be adjusted, determined in step S26 shown in FIG. 4.

FIG. 21 is a schematic diagram showing an example where a test regionextends up to a point where the threshold is exceeded.

FIG. 22 is a schematic diagram showing an example where a test regionextends up to a point where a pole of power range is obtained inaddition to the procedure of the example shown in FIG. 21.

FIG. 23 is a schematic diagram showing an example where a range betweentwo points in the vicinity of the threshold is used as a power range.

FIG. 24 is a schematic diagram showing an example where power value ischanged by a smaller step size over the power range.

FIG. 25 is a schematic diagram showing an example where a test regionextends up to a point where a pole of power range is obtained inaddition to the procedure of the example shown in FIG. 24.

FIG. 26 is a schematic diagram showing an example where pulse width ischanged up to a point where the threshold is exceeded and the range ofchange is used as a test region.

FIG. 27 is a schematic diagram showing an example where a test regionextends up to a point where a pole of pulse range is obtained inaddition to the procedure of the example shown in FIG. 26.

FIG. 28 is a schematic diagram showing an example where pulse width ischanged by a smaller step size over the pulse range.

FIG. 29 is a schematic diagram showing an example where a test regionextends up to a point where a pole of minimum jitter is obtained inaddition to the procedure of the example shown in FIG. 21.

FIG. 30 is a schematic diagram showing an example where a test regionextends up to a point where a pole of minimum jitter is obtained inaddition to the procedure of the example shown in FIG. 26.

FIG. 31 a schematic diagram showing a method for determining a testcondition based on ID information stored on a medium.

FIG. 32 is a schematic diagram showing playback characteristics obtainedby a method according to a related art, shown in FIG. 31.

FIG. 33 is a schematic diagram showing features of a method according toa related art.

FIG. 34 is a schematic diagram showing features of methods according torelated arts.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Features of test recording, which constitute main features of thepresent invention, will be described followed by overview and detail ofpreferred embodiments of the present invention.

FIG. 1 is a schematic diagram showing features of test recordingaccording to an embodiment of the present invention. As shown in FIG. 1,according to this embodiment, test recording is carried out whilechanging power and pulse width of recording pulse 10 in a stepwisemanner. A region of test conditions used in test recording (hereinafterreferred to as a “test region”), when represented by a matrix image ofpower×pulse width, for example, is a region 100 concentrated at a partof the matrix as shown in FIG. 1.

The reason for concentrating test conditions at a part is that optimalconditions can be found by a smaller number of times of test recordingwhere the probability of existence of suitable recording conditions ishigh.

FIG. 2 is a diagram showing jitter characteristics in relation to changein power and pulse width. As shown in FIG. 2, pulse width, which is arecording condition, is changed as a, b, c, d, and e, and power ischanged continuously in a range of P1 to P3 for each of the pulse widthsa, b, c, d, and e, whereby jitter characteristics 102 a to 102 erepresent different characteristic curves for the respective pulsewidths are obtained.

With regard to minimum values of the respective jitter characteristics102 a to 102 e, i.e., the poles of the characteristic curves, in thisexample, the jitter characteristics 102 c obtained by changing powerwith the pulse width has lowest jitter value, so that it is understoodthat this value is most desirable among the jitter characteristics 102 ato 102 e.

Thus, in the example shown in FIG. 2, power P2 and pulse width c, withwhich jitter is minimized, are optimal condition, so that thisembodiment is directed to find these conditions by a minimum number oftimes of testing. Thus, in this embodiment, a threshold of jitter isset, and a region in which the threshold is not exceeded is estimated bytesting recording characteristics prior to test recording, a region witha high probability is selected as a test region, and the test region istested with focus, so that optimal conditions are found by a smallnumber of times of testing.

FIG. 3 is a block diagram showing the overall construction of arecording system including a medium and a drive according to anembodiment of the present invention. As shown in FIG. 3, the recordingsystem includes a drive 20 according to this embodiment, and a medium 16for recording by the drive 20. The medium 16 is an optical informationrecording medium, for example, a dye-based medium such as a CD-R or aDVD-R, or a phase-change medium such as a CD-RW or a DVD-RW.

As shown in FIG. 3, the drive 20 includes a pickup 30 that forms anoptical system for irradiating the medium 16 with laser beams, a servodetector 32 for detecting geometric information such as a controlposition of the pickup 30, an RF detector 34 for detecting an RF signalobtained by the pickup 30, an LD controller 36 for controlling a laserdiode provided in the pickup 30, a memory 38 storing control conditionsor the like of the LD controller 36, a tracking controller 40 forcontrolling tracking of the pickup 30 based on the result of detectionby the servo controller 32, and a focus controller 42 for controllingfocusing of the pickup 30.

The components of the drive 20 are described in patent documentsmentioned earlier and are well known to those skilled in the art, sothat detailed descriptions thereof will be omitted herein.

Among the components, the LD controller 36 and the memory 38particularly relate to test recording, which constitutes a main featureof this embodiment. The LD controller 36 outputs a parameter for a laserbeam for irradiating the medium 16 therewith, i.e., recording pulse 10shown in FIG. 1, to the pickup 30, thereby controlling recordingcondition. The memory 38 stores a pulse pattern of the recording pulse10 and other conditions.

FIG. 4 is a flowchart showing a procedure that is executed by the drive20 according to this embodiment. As shown in FIG. 4, the drive 20executes steps S10 to S14 to make initial setting of the drive 20. Then,the drive 20 executes steps S16 to S22 to determine a condition for testrecording. Then, the drive 20 executes step S24 to execute testrecording by the condition determined. Then, the drive 20 executes stepS26 to determine a condition for actual recording based on the result ofthe test recording. Then, the drive 20 executes step S28 to recordinformation on the medium 16 by the condition determined. Now, thesesteps will be described in more detail.

Determining Reference Condition

In step S10 shown in FIG. 4, test recording is carried out whilechanging recording speed using a standard medium, thereby obtaining onepulse width and three power values as reference conditions. Preferably,the three power values are a power value with which jitter is minimizedas a result of the test recording and two power values above and belowof that power value. Preferably, the two power values are values in thevicinity of a threshold that serves as a reference for determining aresult of jitter test. These reference conditions are used for latertesting of recording characteristics.

Determining Reference Threshold

As described earlier, it is supposed in this embodiment that a regionwhere a jitter threshold is not exceeded is set as a most probable testregion, so that the jitter threshold that serves as a reference must bedetermined. The threshold may be a standard value determined in advancein accordance with the type of the drive or medium. However, thethreshold representing a minimum line of an allowable region of jittervaries depending on the status of the pickup 30 or other componentsshown in FIG. 3, and also varies depending on the recording speed forthe medium.

Thus, preferably, the threshold is also determined on the basis of acombination of a drive and a medium that are actually used so that amore appropriate reference will be used and a more appropriate testregion will be set.

It is to be noted, however, that setting a threshold on the basis of acombination of a drive and a medium causes an increase in the number ofrecording steps. Thus, alternatively, a threshold that is suitable foran individual drive may be stored in the memory 38 at the time ofmanufacturing, assuming that variation among individual drives is a mainfactor of variation in the threshold.

FIG. 5 is a flowchart showing details of the step of determining areference threshold, shown in FIG. 4. As shown in FIG. 5, to determine areference threshold, recording and playback are carried out based on apredetermined recording condition, a reference value for the system isdetermined based on the result, and a value obtained by setting apredetermined margin to the reference value is used as a threshold fordetermining a test region. Now, these steps will be described in order.

In step S50, a recording condition is set. In step S50, a predeterminednumber of patterns of conditions needed for recording and playback, suchas pulse width, power, recording and playback speed, and recordingaddress, are prepared, and the recording conditions are set to the drive20. Then, a reference medium is loaded in the drive 20. Preferably, amedium having standard characteristics among various media is chosen asthe reference medium.

In step S52, recording and playback are carried out using the referencemedium loaded, based on the recording conditions set in step S50,thereby obtaining recording and playback characteristic values by therespective recording conditions, such as jitter. As the characteristicvalue, a value representing recording quality is obtained.

In step S54, an optimal value, for example, a minimum value of jitter,is selected as a system reference value from the recording and playbackcharacteristic values obtained in step S52. Thus, a jitter value that ispresumably approximate to the optimal value for the drive 20 is set as areference value. The reference value need not be an optimal point ofjitter, and may be an intermediate point of two points crossing apredetermined threshold, i.e., an intermediate value of power margin.

In step S56, the system reference value determined in step S54 ismultiplied by a predetermined coefficient α (preferably, α>1) tocalculate a threshold. Thus, a predetermined margin is provided withrespect to the system reference value. That is, the threshold iscalculated by multiplying the system reference value by α, where α ispreferably about 1.5. The coefficient α is set suitably in accordancewith the type of the drive or medium used. The coefficient α may be setin a range of 0.8 to 1.2 so that the threshold will be close to thesystem reference value, or in a range of 2.0 to 3.0 so that thethreshold will be larger.

FIG. 6 is a schematic diagram showing an example relating to the flowshown in FIG. 5. In the example shown in FIG. 6, a jitter value is usedas a characteristic value representing recording quality, and the valueof power is changed from P1 to P6 for each of pulse widths W1 to W4,thereby obtaining playback characteristics 102-1 to 102-4. In theexample shown in FIG. 6, the pulse widths W1 to W4 and the power valuesP1 to P6 are used as recording conditions. The pole of the playbackcharacteristics 102-3 with which jitter value is minimized is used as asystem reference value, and a value obtained by multiplying the systemreference value by, for example, 1.5 is used as a threshold. The arrowsin the matrix image shown in FIG. 6 indicate directions of changing testconditions. This also applies to the subsequent figures.

FIG. 7 is a schematic diagram showing an example relating to the flowshown in FIG. 5. In the example shown in FIG. 7, a jitter value is usedas a characteristic value representing recording quality, and the rangeof changing power value is varied among the pulse widths W1 to W4,thereby obtaining playback characteristics 102-1 to 102-4. In theexample shown in FIG. 7, the pole of the playback characteristics 102-2with which the jitter value is minimized is used as a system referencevalue, and a value obtained by multiplying the system reference valueby, for example, 1.5 is used as a threshold. As described above, athreshold may be determined using different power conditions forrespective pulse widths.

Initial Setting of Recording Apparatus

In step S14, the reference condition and the reference thresholdobtained in steps S10 and S12 shown in FIG. 4 are stored in the memory38 of the drive 20. Preferably, step S14 is executed at the time ofmanufacturing of the drive 20.

Loading of Recording Medium

Then, in step S16, the medium 16 for recording information thereon isloaded in the drive 20 in which initial setting has been completed instep S14.

Recording and Playback by Reference Condition

Then, in step S18, recording is carried out on the medium 16 loaded instep S16, by the conditions set in step S14. More specifically, jittervalues at three points are obtained by carrying out recording andplayback three times using the single pulse width and three power valuesdefined as reference conditions. The recording characteristics inrelation to combinations of the drive 20 and the medium 16 can beunderstood by plotting the jitter values at the three points along apower axis.

Testing of Recording Characteristics

FIGS. 8A and 8B are schematic diagrams showing examples where valleypatterns are obtained as results of testing recording characteristics instep S20 shown in FIG. 4. As shown in FIGS. 8A and 8B, recordingcharacteristics are tested using the jitter values and threshold for therespective reference conditions obtained in the preceding steps. In theexamples shown in FIGS. 5A and 5B, power values P1, P2, and P3 are usedas reference conditions, and a virtual line connecting jitter valuesobtained in relation to the respective power values forms a valleypattern. When such a valley pattern is obtained, it is indicated thatthe reference medium used in step S10 and the recording medium loaded instep S16 have substantially the same sensitivity and similar recordingcharacteristics.

FIG. 8A shows an example where the minimum value of the valley patternis not larger than the threshold, and FIG. 8B shows an example where theminimum value of the valley pattern is not smaller than the threshold.In either case, it is presumed that the reference medium and therecording medium have substantially the same sensitivity. When thereference medium and the recording medium have substantially the samesensitivity, a condition used for test recording is set as a surfacearea defined by power×pulse width around the reference condition, asdescribed later.

In FIGS. 8A and 8B, the difference between a playback value and aplayback reference value obtained at each of the recording points P1,P2, and P3, i.e., the difference between the jitter value and the jitterthreshold in the examples shown in FIGS. 8A and 8B, differs. Morespecifically, the playback value is closer to the playback referencevalue in FIG. 8A than in FIG. 8B.

This indicates that it is easier to find an optimal condition in theexample shown in FIG. 8A than in the example shown in FIG. 8B. Thus,testing may be carried out smaller number of times in the example shownin FIG. 5A than in the example shown in FIG. 8B, finding an optimalsolution by a smaller number times of testing.

That is, when the difference between the playback value and the playbackreference value is small, the optimal condition becomes closer to thereference condition. On the other hand, when the difference between theplayback value and the playback reference value is large, the optimalcondition becomes more remote from the reference condition. Thus, whenit is desired to decrease the number of times of testing, the number oftimes of testing is preferably changed in accordance with the differencebetween the playback value and the reference playback value.

FIGS. 9A and 9B are schematic diagrams showing examples whereright-decreasing patterns are obtained as results of testing recordingcharacteristics in step S20 shown in FIG. 4. In the examples shown inFIGS. 9A and 9B, right-decreasing patterns are obtained, in which thejitter value decreases as the power value increases as P1, P2, and P3.When such a right-decreasing pattern is obtained, it is indicated thatthe sensitivity of the recording medium is lower than the sensitivity ofthe reference medium.

FIG. 9A shows an example where the minimum value of the right-decreasingpattern is not larger than the threshold, and FIG. 9B shows an examplewhere the minimum value of the right-decreasing pattern is not smallerthan the threshold. In either case, it is presumed that the sensitivityof the recording medium is lower than the sensitivity of the referencemedium. When the sensitivity of the recording medium is lower, a testregion defined by a surface area of power×pulse width around thereference condition is shifted to the side of high power and wide pulsewidth for test recording, as will be described later.

Furthermore, when such a right-decreasing pattern shown in FIGS. 9A and9B is obtained, the minimum value of jitter presumably exists on theside of high power, so that additional writing may be performed at apower higher than P3 to check recording characteristics again. In thiscase, although the number of times of recording increases by one, theprecision of testing of recording characteristics is improved. When sucha pattern is obtained, similarly to the case where a valley pattern isobtained, the number of times of testing may be changed in accordancewith the difference between playback value and playback reference value.

Furthermore, when such a right-decreasing pattern shown in FIGS. 9A and9B is obtained, presumably, the optimal solution becomes more remotefrom the reference condition than in the valley patterns shown in FIGS.5A and 8B, so that the number of times of testing is preferably beingincreased than in the case of the valley patterns.

FIGS. 10A and 10B are schematic diagrams showing examples whereright-increasing patterns are obtained as results of testing recordingcharacteristics in step S20 shown in FIG. 4. In the examples shown inFIGS. 10A and 10B, right-increasing patterns are formed in which thejitter value increases as the power value increases as P1, P2, and P3.When such right-increasing patterns are obtained, it is indicated thatthe sensitivity of the recording medium is higher than the sensitivityof the reference medium.

FIG. 10A shows an example where the minimum value of theright-increasing pattern is not larger than the threshold, and FIG. 10Bshows an example where the minimum value of the right-increasing patternis not smaller than the threshold. In either case, it is presumed thatthe sensitivity of the recording medium is higher than the sensitivityof the reference medium. When the sensitivity of the recording medium ishigher, a test region defined by a surface area of power×pulse widtharound the reference condition is shifted to the side of low power andnarrow pulse width for test recording, as will be described later.

Furthermore, when such right-increasing patterns shown in FIGS. 10A and10B are obtained, the minimum value of jitter presumably exists on theside of low power, so that additional writing may be performed at apower lower than P1 to check recording characteristics again. In thiscase, although the number of times of recording is increased by one, theprecision of testing of recording characteristics is improved. When suchpatterns are obtained, similarly to the case where the valley patternsare obtained, the number of times of testing may be changed inaccordance with the difference between playback value and playbackreference value.

Furthermore, when such right-increasing patterns shown in FIGS. 10A and10B are obtained, presumably, the optimal solution becomes more remotefrom the reference condition than in the valley patterns shown in FIGS.5A and 8B. Thus, preferably, the number of times of testing is increasedcompared with the case of the valley patterns.

Determining Test Region

FIG. 11 is a schematic diagram showing an example where a test region isdetermined in step S22 in a case where a valley pattern is obtained instep S20 shown in FIG. 4. As shown in FIG. 11, when a valley pattern isobtained, the power value for test recording is changed in a power rangedefined by cross points between the threshold and an approximated curve106 drawn by jitter values obtained for P1, P2, and P3, respectively. Inthis embodiment, a “power range” is defined as a range of power that isactually used in test recording, and a “power margin” is defined as arange of power with which jitter does not exceed a threshold.

The approximated curve 106 differs depending on pulse width. Thus,letting a pulse width used as a reference condition be denoted as W4,recording is carried out at power values P1, P2, and P3 for each of thepulse widths W1 to W6 centered around W4, checking cross points betweenthe threshold and approximated curves 106 thereby obtained. Thus, asrepresented in the matrix image shown in FIG. 11, a power range wherejitter does not exceed the threshold is obtained for each of the pulsewidths, and a hatched region shown in FIG. 11 is used as a test region.The three power conditions P1, P2, and P3 and the pulse width W4 used asreference condition correspond to 108-1, 108-2, and 108-3 in the matriximage shown in FIG. 11. The test region is set as a surface regiondefined by power×pulse width around the reference condition.

By obtaining a power range for each pulse width as described above, aregion where jitter does not exceed the threshold can be tested in aconcentrated manner, so that a suitable condition can be found by asmaller number of times of testing.

The number of times of testing can also be reduced by setting a largerstep size of changing power value when the power margin is large andsetting a smaller step size of changing power value when the powermargin is small. For example, when the power margin is 10 mW, it ispresumed that rough testing suffices to obtain an optimal value, so thattesting is carried out five times with a step size of 2 mW, and when thepower margin is 1 mW, it is presumed that more precise testing isneeded, so that testing is carried out ten times with a step size of 0.1mW.

FIG. 12 is a schematic diagram showing an example where a test region isdetermined in step S22 when a right-decreasing pattern is obtained instep S20 shown in FIG. 4. When a right-decreasing pattern is obtained,it is presumed that the optimal parameter exists on the side of highpower, as shown in FIG. 12. Thus, additional recording is carried out ata power value P+ that is higher than P3, and a range defined by crosspoints between the threshold and an approximated curve 106 drawn byjitter values obtained for P1, P2, P3, and P+, respectively, is used asa power range. This processing is carried out for each of the pulsewidths W1 to W6, obtaining a test region represented in the matrix imageshown in FIG. 12.

The test region determined by the procedure described above is shiftedto the side of high power compared with the surface region defined bypower×pulse width and centered around the reference conditions 108-1,108-2, and 108-3. Although W1 to W6 used for the valley pattern are usedin this example, since a right-decreasing pattern indicates a lowersensitivity, W1 to W6 may be shifted to the side of wide pulse width indetermining a power range.

FIG. 13 is a schematic diagram showing an example where a test region isdetermined in step S22 when a right-increasing pattern is obtained instep S20 shown in FIG. 4. When a right-increasing pattern is obtained,it is presumed that the optimal parameter exists on the side of lowpower, as shown in FIG. 13. Thus, additional recording is carried out ata power value P+ that is lower than P1, and a power range is defined bycross points between the threshold and an approximated curve 106 drawnby jitter values obtained for P+, P1, P2, and P3, respectively. Thisprocessing is carried out for each of the pulse widths W1 to W6,obtaining a test region represented in the matrix image shown in FIG.13.

The test region determined by the procedure described above is shiftedto the side of low power compared with the surface region defined bypower×pulse width and centered around the reference conditions 108-1,108-2, and 108-3. Although W1 to W6 used for the valley pattern are usedin this example, since a right-increasing pattern indicates a highsensitivity, W1 to W6 may be shifted to the side of narrow pulse widthin determining a power range.

That is, according to the method described above, recordingcharacteristics are tested for each pulse width, and the number of timesof testing is determined for each pulse width according to results ofthe testing. Thus, reduction in the number of times of testing isexpected. The testing of recording characteristics, described above, isan example where change in jitter by recording at the referencecondition is patterned. Preferably, the following eight patterns areused.

FIG. 14 is a diagram showing an example where eight patterns are used instep S20 shown in FIG. 4. As shown in FIG. 14, a pattern 1 applies whenthe maximum value of jitter is not larger than the threshold, regardlessof whether the pattern is a valley, right increasing, or rightdecreasing. When this pattern is obtained, it is presumed that thesensitivity of the recording medium is substantially the same as thesensitivity of the reference medium and that a large margin where thejitter value does not exceed the threshold is provided, so that thepower condition is extended on both low power side and high power side.That is, with the pattern 1, since values in the vicinity of thethreshold are not obtained, additional recording is carried out both onthe low power side and the high power side.

Then, jitter characteristics obtained by the additional recording areapproximated by a curve, and the difference between larger and smallertwo values at which the curve crosses the jitter threshold is used as areference value of power range.

Furthermore, when this pattern is obtained, a pulse width region of thereference value ±0.2 T is determined as a test region. In testrecording, an optimal recording condition is determined by changing thepulse width by a step size of 0.2 T. T denotes the length of a unit timeof a recording pit.

Now, let the reference pulse width be a pulse condition 1, and theextended two points be pulse conditions 2 and 3, the pulse conditions 2and 3 for the pattern 1 are pulse widths extended by 0.2 T. Inaccordance with the change in the pulse width condition, the power rangeused as a test condition is also changed.

More specifically, when the pulse width is changed by 0.1 T, the powerrange for the pulse width is defined as the reference value of powerrange×(1−0.05×1) mW. When the pulse width is changed by 0.2 T, the powerrange for the pulse width is defined as the reference value of powerrange×(1−0.05×2) mW. When the pulse width is changed by −0.1 T, thepower range for the pulse width is defined as the reference value ofpower range×(1−0.05×(−1)) mW.

Thus, the following three sets of test conditions are used for thepattern 1.

(1) Reference value of pulse width, and reference value of power range

(2) Reference value of pulse width −0.2 T, and reference value of powerrange×(1−0.05×(−2)) mW

(3) Reference value of pulse width +0.2 T, and reference value of powerrange×(1−0.05×(+2)) mW

In this embodiment, the reference condition (1) need not be used inactual test recording.

A pattern 2 applies when a valley pattern is obtained and the minimumvalue of jitter is not larger than the threshold. When this pattern isobtained, it is determined that the sensitivity of the medium on whichdata is to be recorded and the sensitivity of the reference medium aresubstantially the same, so that reference value ±0.1 T is selected as apulse width condition. Then, a power range is set for each of thesepulse conditions by the same procedure used for the pattern 1. Thus,test conditions that are used when the pattern 2 applies are thefollowing three sets.

(1) Reference value of pulse width, and reference value of power range

(2) Reference value of pulse width −0.1 T, reference value of powerrange×(1−0.05×(−1)) mW

(3) Reference value of pulse width +0.1 T, reference value of powerrange×(1−0.05×(+1)) mW

A pattern 3 applies when a valley pattern is obtained and the minimumvalue of jitter is larger than the threshold. When this pattern isobtained, it is determined that the sensitivity of the medium on whichdata is to be recorded is substantially the same as the sensitivity ofthe reference media, and that difference in the characteristics ofmedium is large, so that reference value ±0.2 T is selected as a pulsewidth condition. Then, a power range is set for each of these pulseconditions by the same procedure used for the pattern 1. Thus, testconditions that are used when the pattern 3 applies are the followingthree sets.

(1) Reference value of pulse width, and reference value of power range

(2) Reference value of pulse width −0.2 T, and reference value of powerrange×(1−0.05×(−2)) mW

(3) Reference value of pulse width +0.2 T, and reference value of powerrange×(1−0.05×(+2)) mW

A pattern 4 applies when a right-decreasing pattern is obtained and theminimum value of jitter is not larger than the threshold. When thispattern is obtained, it is determined that the sensitivity of the mediumon which data is to be recorded is somewhat lower than the sensitivityof the reference medium, so that three points corresponding to thereference value, +0.1 T, and +0.2 T are selected as pulse widthconditions. Then, a power range is set for each of these pulseconditions by the same procedure used for the pattern 1. Thus, testconditions that are used when the pattern 4 applies are the followingthree sets.

(1) Reference value of pulse width, and reference value of power range

(2) Reference value of pulse width +0.1 T, and reference value of powerrange×(1−0.05×(+1)) mW

(3) Reference value of pulse width +0.2 T, and reference value of powerrange×(1−0.05×(+2)) mW

A pattern 5 applies when a right-decreasing pattern is obtained and theminimum value of jitter is larger than the threshold. When this patternis obtained, it is determined that the sensitivity of the medium onwhich data is to be recorded is considerably lower than the sensitivityof the reference medium, so that three points corresponding to thereference value, +0.2 T, and +0.4 T are selected as pulse widthconditions. Then, a power range is set for each of these pulseconditions by the same procedure used for the pattern 1. Thus, testconditions that are used when the pattern 5 applies are the followingthree sets.

(1) Reference value of pulse width, and reference value of power range

(2) Reference value of pulse width +0.2 T, and reference value of powerrange×(1−0.05×(+2)) mW

(3) Reference value of pulse width +0.4 T, and reference value of powerrange×(1−0.05×(+4)) mW

A pattern 6 applies when a right-increasing pattern is obtained and theminimum value of jitter is not larger than the threshold. When thispattern is obtained, it is determined that the sensitivity of the mediumon which data is to be recorded is somewhat higher than the sensitivityof the reference medium, so that three points corresponding to thereference value, −0.1 T, and −0.2 T are selected as pulse widthconditions. Then, a power range is set for each of these pulseconditions by the same procedure use for the pattern 1. Thus, testconditions that are used when the pattern 6 applies are the followingthree sets.

(1) Reference value of pulse width, and reference value of power range

(2) Reference value of pulse width −0.1 T, and reference value of powerrange×(1−0.05×(−1)) mW

(3) Reference value of pulse width −0.2 T, and reference value of powerrange×(1−0.05×(−2)) mW

A pattern 7 applies when a right-increasing pattern is obtained and theminimum value of jitter is larger than the threshold. When this patternis obtained, it is determined that the sensitivity of the medium onwhich data is to be recorded is considerably higher than the sensitivityof the reference medium, so that three points corresponding to thereference value, −0.2 T, and −0.4 T are selected as pulse widthconditions. Then, a power range is set for each of these pulse widthconditions by the same procedure used for the pattern 1. Thus, testconditions that are used when the pattern 7 applies are the followingthree sets.

(1) Reference value of pulse width, and reference value of power range

(2) Reference value of pulse width −0.2 T, and reference value of powerrange×(1−0.05×(−2)) mW

(3) Reference value of pulse width −0.4 T, and reference value of powerrange×(1−0.05×(−4)) mW

A pattern 8 applies when a mountain pattern is obtained and the maximumvalue of jitter is larger than the threshold. When this pattern isobtained, it is determined that the pattern is abnormal, so that thereference value ±0.2 T are selected as pulse width conditions. Then, apower range is set for each of these pulse width conditions by the sameprocedure used for the pattern 1. Thus, test conditions that are usedwhen the pattern 8 applies are the following three sets.

(1) Reference value of pulse width, and reference value of power range

(2) Reference value of pulse width −0.2 T, and reference value of powerrange×(1−0.05×(−2)) mW

(3) Reference value of pulse width +0.2 T, and reference value of powerrange×(1−0.05×(+2)) mW

Of the eight patterns described above, when patterns other than thepattern 2, which is most approximate to the characteristics of thereference medium, are detected, in order to confirm that the patterndetected is not due to an incorrect playback operation, the recordingresult that has caused the pattern may be played back again to detectjitter. In this case, when characteristics other than the pattern 2 aredetected, recording conditions are added or extended according to theconditions shown in FIG. 14.

When the pattern 8 is detected by the confirmation of an incorrectplayback operation, it is possible that an incorrect recording operationhas occurred. Thus, recording is performed again at the reference valueof pulse width before performing additional recording and extendingpulse width. When the pattern 8 is again obtained by the recording,additional recording, i.e., extending power to measure a margin for thepulse condition 1, is not carried out, and pulse conditions 2 and 3 areextended. The power value is extended in accordance with the extensionof the pulse conditions 2 and 3 by the method described earlier.

That is, in the case of the pattern 8, a margin is not provided with thepulse condition 1 and a power range that serves as a reference forextension is not obtained, so that an initial power condition range isset as a reference power range.

Determining Test Region: Determining Power Range by Approximation

By executing the procedure described above, a test region that iseffective for obtaining an optimal solution by a small number of timesof testing is determined. Now, a method of determining a power range,which is important in determining a test region, will be described.

In this embodiment, in order to improve the accuracy of finding anoptimal solution by a minimum number of times of testing, testconditions are concentrated to a region where the jitter value does notexceed the threshold, as described earlier. According to this scheme, apower range that is used in test recording is calculated from powervalues at larger and smaller two points defining a margin with respectto the threshold. The margin with respect to the threshold refers to aregion where characteristic values not exceeding the threshold areobtained. The power values at larger and smaller points refer to a valueon the low power side and a value on the high power side defining thewidth of the margin.

Considering the reduction in test recording time of various media, andthe efficiency of test region of a medium having restriction on a testrecording region, such as a write-once medium, the number of recordingpoints needed for test recording should preferably be minimized.However, since the power range to be obtained is an important parameterthat serves as a criterion for determining an optimal recordingcondition, a high precision is desired.

A precise power range means concentrated testing of a selected region,so that the number of times of testing is reduced. For example, whentest recording is performed at a frequency of once per 0.1 mW, testrecording is performed ten times when the power range is 1 mW, and testrecording is performed twenty times when the power range is 2 mW. Thus,narrowing the power range contributes to reduction in the number oftimes of testing.

Thus, in this embodiment, considering that the recording quality ofrecording and playback signals changes like a quadratic curve with apole at an optimal point with respect to recording power, acharacteristic curve is approximated using several recording points todetermine an amount of margin. By using such an approximation method, itis possible to readily and precisely determine a power range based onseveral recording points, serving to reduce the number of times oftesting.

FIG. 15 is a schematic diagram for explaining a method of obtaining apower range used in step S22 shown in FIG. 4 by curve approximation. Asshown in FIG. 15, to carry out approximation, first, two points a and con the low power side and the high power side, respectively, at whichthe Jitter value that serves as a criterion for determining recordingcharacteristics is in the vicinity of the threshold, and a point bbetween the points a and c, at which the jitter value is smaller thanthe threshold or the values at the points a and c, are selected. Thatis, the points a, b, and c have the following relationship.

a>b, c>b, threshold>b

As shown in FIG. 15, the vicinity of the threshold is defined as a rangebetween an upper limit and a lower limit having a certain width withrespect to the threshold. Preferably, the upper limit is set to be 40%of the threshold, and the lower limit is set to be 5% of the threshold.Then, the values of a, b, and c are approximated by a quadraticfunction, and a power range is defined by the difference between largerand smaller two points where the quadratic curve crosses the threshold.The range that is defined as the vicinity of the threshold may bechanged suitably in consideration of the interval of recording points,for example, to −5% to +40% or −10% to 30%.

FIG. 16 is a schematic diagram showing another example where a powerrange used in step S22 shown in FIG. 4 is obtained by a curveapproximation. As shown in FIG. 16, when a relationship satisfying a>b,c>b, and threshold>b is not obtained with the three conditions A, B, andC alone, preferably, a condition D on the high power side is added toobtain a value in the vicinity of the threshold.

Furthermore, as shown in FIG. 16, when a relationship of B>C exists,preferably, an approximate equation is calculated with three points A,C, and D without using B.

The relationship between the three recording points and the threshold inthis case is A>C, D>C, and threshold>C, which is suitable for drawing anapproximated curve, so that a precise approximated curve is obtained bythree-point approximation. The additional recording condition indicatedat D is determined by A>B, B>C, and the threshold indicated by recordingpoints before addition.

On the contrary to FIG. 15, when a value in the vicinity of thethreshold is absent on the low power side, additional recording isperformed at a power condition lower than A. Depending on therelationship between the recording points and the threshold, one or morerecording conditions may be added.

Furthermore, the range of power used as additional recording conditionsmay be changed based on a predetermined power step size, or powerconditions may be set based on relationship between power variation andjitter variation obtained in advance.

When recording points sufficient to obtain a power range are notobtained even after adding recording conditions as described above,recording points are changed by again adding recording conditions by thesame procedure described above.

Furthermore, in a case where test recording region is restricted, suchas in the case of a write-once medium, in order to avoid using anenormous testing time, an upper limit may be set to the number of timesrecording conditions are added. Furthermore, an upper limit of power foradditional recording may be set so that recording power will not exceeda laser output value by adding recording conditions.

Furthermore, although a power range is determined by three-pointapproximation in the example described above, alternatively, a powerrange may be determined by based on the difference between power valuesat larger and smaller two points that are most approximate to thethreshold.

Alternatively, two points in the vicinity of the threshold may beselected by performing recording while changing power until larger andsmaller two points across the threshold are found, and two points thatare most approximate to the threshold may be selected, or the two pointsthemselves may be selected. The methods will be described in moredetail.

Determining Test Region: Determining Power Range by Sampling

FIG. 17 is a schematic diagram showing an example where a power rangeused in step S22 shown in FIG. 4 is determined by sampling. In theexample shown in FIG. 17, instead of the three-point approximationdescribed earlier, power is gradually changed until values approximateto the threshold is obtained, a power range is determined based on powervalues at larger and smaller two points in the vicinity of thethreshold.

More specifically, as shown in FIG. 17, recording power is increasedsequentially as P1, P2, P3, . . . to carry out recording and playbackuntil a power value P6 at which a value not smaller than the thresholdis obtained. As shown in a matrix image in FIG. 17, power is changedover P1 to P6, and a power range is defined between P2 on the low powerside and P6 on the high power side that are most approximate to thethreshold. As described above, a power range can be determined byselecting two points across the threshold.

A method for selecting large and smaller points in the vicinity of thethreshold can be selected as appropriate from the following.

1) Select larger and smaller two points defining a power margin. Thatis, select two points that are most approximate to a playback referencevalue within a power range satisfying the playback reference value.

2) Select two points that are most approximate to a playback referencevalue although somewhat outside of a power margin.

3) Select larger and smaller two points across a playback referencevalue on the low power side.

4) Select larger and smaller two points across a playback referencevalue on the high power side.

5) Select two points that are most approximate to a playback referencevalue and that are located across the playback reference value on thelow power side and the high power side.

It is also possible to approximate recording characteristics using twopoints selected by one of the above methods, determining two points atwhich the recording characteristics cross the playback reference value.

Test Recording

FIGS. 18A and 18B are schematic diagrams showing examples of pulsepattern used in test recording in step S24 shown in FIG. 4. FIG. 18Ashows an example where a single-pulse pattern is used. FIG. 18B shows anexample where a multiple-pulse pattern is used. As shown in FIGS. 18Aand 18B, a single-pulse pattern 10-1 and a multiple-pulse pattern 10-2each include a leading pulse 12 at the beginning of the pattern and atrailing pulse 14 at the end of the pattern. The amount of energy of theentire recording pulse is defined by the height of main power PW, andthe amount of energy at the first stage applied to an edge of arecording pit is defined by the length of the leading pulse width Ttop.PWD indicated by a dotted line is a region used for delicate control ofthe amount of energy, which will be described later.

Preferably, the main power PW has a highest value in the recording pulse10-1 and 10-2. The leading pulse width Ttop has a width corresponding toa recording pit having a length of 3 T. Since recording pulses havingthis width have the highest frequency of occurrence and has much effecton recording quality, preferably, the leading pulse width Ttop ischanged in test recording.

As shown in FIGS. 18A and 18B, in either case where the single-pulsepattern or the multiple-pulse pattern is used, the value of test powerdetermined by the preceding steps is used as the main power PW, and thewidth of the test pulse is used as the leading pulse width Ttop.

As described above, test recording is carried out on the medium loadedin step S16 shown in FIG. 4 while changing the main power PW and theleading pulse width Ttop in a stepwise manner, and playback is carriedout based on recording pits formed by the test recording, therebyobtaining a jitter value for each test condition.

Then, test recording is carried out once more using a predeterminedpattern of pits and lands to examine other adjustment factors such asmismatch between recording pulses and recording pits. Then, the seriesof test recording operations is finished.

Determining Recording Condition

Through the test recording described above, values of the main power PWand the leading pulse width Ttop with which the jitter value isminimized, and parameters for adjusting other factors are determined,and these values are used as a recording condition suitable or thecombination of the drive and the medium used.

FIGS. 19A and 19B are schematic diagrams showing examples of adjustmentof other factors determined in step S26 shown in FIG. 4. FIG. 19A showsan example where a single-pulse pattern is used. FIG. 19B shows anexample where a multiple-pulse pattern is used.

As shown in FIG. 19A, in the case of the single-pulse pattern 10-1, aregion of low power that is lower than the main power PW by PWD isprovided between the leading pulse 12 and the trailing pulse 14 asanother factor to be adjusted. By defining this amount, recording pitsare prevented from forming a teardrop shape. Similarly, in the case ofthe multiple-pulse pattern 10-2, as shown in FIG. 19B, by defining thewidth Tmp of an intermediate pulse between the leading pulse 12 and thetrailing pulse 14, recording pits are prevented from forming a teardropshape.

FIGS. 20A and 20B are schematic diagrams showing examples of otherfactors to be adjusted, determined in step S26 shown in FIG. 4.Similarly to FIGS. 18A and 18B, FIG. 20A shows an example where asingle-pulse pattern is used, and FIG. 20B shows an example where amultiple-pulse pattern is used.

As shown in FIGS. 20A and 20B, in either case where the single-pulsepattern 10-1 or the multiple-pulse pattern 10-2 is used, Ttopr foradjusting the starting position of the leading pulse 12, and Tlast foradjusting the ending position of the trailing pulse 14 are set as otherfactors to be adjusted. By adjusting these values, a pulse pattern withwhich a pit length after recording has an appropriate value is selected.

The main power PW, the leading pulse width Ttop, the low power regionPWD, the leading pulse position Ttopr, and the trailing pulse positionTlast, obtained by the procedure described above, are stored in thememory 38 shown in FIG. 3. Then, the determination of recordingcondition is completed.

Recording of Information

The LD controller 36 shown in FIG. 3 generates recording pulses forinformation to be recorded, input to the drive 20 from the outside,based on various recording conditions stored in the memory 38 by theprocedure described above, and outputs the recording pulses to thepickup 30. Thus, the information is recorded on the medium 16.

Another Embodiment of Determining Test Region

Next, another embodiment of determining a test region, which constitutesa feature of the present invention, will be described.

FIG. 21 is a schematic diagram showing an example where the test regionextends up to a point where the jitter value exceeds the threshold. Inthe example shown in FIG. 21, the power used in test recording ischanged as P1, P2, . . . to P6 at which the jitter value exceeds thethreshold. As represented in an image matrix, the power is discretelychanged from P1, P2, . . . to P6 for a pulse width, and the power valueP4 with which the jitter value is minimized is used as a recordingcondition 104. In this case, the power range is defined by P1 to P6 overwhich the power is changed, and a range of P2 to P6 that is close to theregion where the threshold is not exceeded serves as a power margin. Asdescribed above, the test region extends up to a point where thethreshold is reached, so that the number of times of testing is reducedcompared with a case where testing is carried out over a constant powerrange.

FIG. 22 is a schematic diagram showing an example where a test regionextends up to a point where a pole of power range is obtained. In theexample shown in FIG. 22, in addition to the procedure of the exampleshown in FIG. 21, pulse width is changed, and the poles of power rangeor power margin obtained for the respective pulse widths are used asrecording conditions. In this example, while sequentially changing pulsewidth as W1, W2, . . . , power is changed for each of the pulse widthsup to a point where the threshold is reached as shown in FIG. 21, andthis step is repeated until a pulse width W4 with which power range orpower margin is maximized is identified.

The pole of power range or power margin can be identified by examiningthe amount of change between values of adjacent sample points. Thus,when the pulse width W4 is a pole, test recording is carried out up toW5, which is immediately subsequent to W4. The power range and powermargin differ among the pulse widths, so that the hatched region thatare tested differs depending on the pulse width.

When the pulse width W4 is a pole, the pulse width W4 and a power P3with which the jitter value is minimized for the pulse width W4 are usedas a recording condition 104. As described above, by changing the pulsewidth in addition to the procedure of the example shown in FIG. 21, thetest region can be extended in the direction of pulse width by a smallnumber of times of testing.

FIG. 23 is a schematic diagram showing an example where a power range isdefined by two points in the vicinity of the threshold. In the exampleshown in FIG. 23, the power value is gradually changed until a value inthe vicinity of the threshold is obtained, and a power range isdetermined based on larger and smaller power values at two points in thevicinity of the threshold. The procedure for this example is the same asthat in the example shown in FIG. 17, so that a description thereof willbe omitted.

This example differs from the example shown in FIG. 21 in that insteadof testing sampling points between P2 and P6 alone, after determining apower range, the power is changed by a smaller step size over the rangeto determine a more suitable condition.

FIG. 24 is a schematic diagram showing an example where the power valueis changed by a smaller step size over the power range. As shown in FIG.24, the power value is changed by a smaller step size over the powerrange P2 to P6, and a power value with which the jitter value isminimized is used as a recording condition 104. As described above, byexamining the power range by a smaller step size, a value approximate toan optimal value is obtained. In this example, an optimal point is foundbetween P3 and P4.

FIG. 25 is a schematic diagram showing an example where a test regionextends up to a point where a pole of power range is obtained inaddition to the procedure of the example shown in FIG. 24. In theexample shown in FIG. 25, the pulse width is changed in addition to theprocedure of the example shown in FIG. 24, and a pole of power range orpower margin obtained for each pulse width is used as a recordingcondition. This scheme is the same as the scheme of applying theprocedure of the example shown in FIG. 21 to the example shown in FIG.22, so that a description thereof will be omitted.

FIG. 26 is a schematic diagram showing an example where the pulse widthis changed up to a point where the jitter value exceeds the threshold,and the range of changing the pulse width is used as a test region. Inthe example shown in FIG. 26, the pulse width used for test recording issequentially changed as W1, W2, . . . , and the test recording isfinished at W6 at which the jitter value exceeds the threshold. Asrepresented by an image matrix, the pulse width is sequentially changedas W1, W2, . . . W6 for the power P1, and the pulse width W4 with whichthe jitter value is minimized among W1 to W6 is used as a recordingcondition 104. In this case, the pulse range to be tested is W1 to W6over which the pulse width is changed, and the pulse margin is W2 to W6that is close to a region where the jitter value does not exceed thethreshold. As described above, by using a test region extending up to apoint where the jitter value reaches the threshold, the number of timesof testing is reduced compared with a case where a fixed pulse range isalways used for testing.

FIG. 27 is a schematic diagram where the test region extends up to apoint where a pole of pulse range is obtained. In the example shown inFIG. 27, in addition to the procedure of the example shown in FIG. 26,the power value is changed and a pole of pulse range or pulse margindetermined for each power value is used as a recording condition. Inthis example, while sequentially changing the power value as P1, P2, . .. , the pulse width is changed for each power value until the jittervalue reaches the threshold shown in FIG. 26, and this step is repeateduntil power P4 with which the pulse range or pulse margin is maximizedis identified.

The pole of pulse range or pulse margin can be identified by examiningthe amount of change between values at adjacent sample points. Thus,when the power P4 is a pole, test recording is carried out up to P5,which is immediately subsequent to the power P4. Since the pulse rangeand pulse margin differ depending on the power value, the hatched regionto be tested differs depending on the power value, as represented in thematrix image shown in FIG. 27.

When the power P4 is a pole, the power P4 and the pulse width W3 withwhich the jitter value is minimized for the power P4 are used as arecording condition 104. As described above, by changing the power valuein addition to the procedure of the example shown in FIG. 26, the testregion can be extended in the direction of power by a small number oftimes of testing.

FIG. 28 is a schematic diagram showing an example where the power valueis changed over the pulse range by a smaller step size. As shown in FIG.28, the power value is changed by a smaller step size over P3 to P5 inthe vicinity of the pole of the pulse range identified in FIG. 27, and acondition with which the jitter value is minimized is used as arecording condition 104. As described above, by changing the power valuein the vicinity of the pole by a smaller step size, a value approximateto an optimal value can be found. In this example, an optimal point isfound between P3 and P4.

FIG. 29 is a schematic diagram showing an example where the test regionextends up to a point where the pole of minimum jitter is obtained, inaddition to the procedure of the example shown in FIG. 21. In theexample shown in FIG. 29, in addition to the procedure of the exampleshown in FIG. 21, the pulse width is changed and the pole of minimumjitter determined for each pulse width is used as a recording condition.In this example, the pulse width is sequentially changed as W1, W2, . .. , and the procedure shown in FIG. 21 is executed for each of the pulsewidths. While comparing the minimum jitter values thereby obtained, thisstep is repeated until a pulse width W4 with which the jitter value isminimized is identified.

The pole of minimum jitter value can be identified by examining theamount of change between values at adjacent sample points. Thus, whenthe pulse width W4 is a pole, test recording is carried out up to W5,which is immediately subsequent to W4. Since the minimum jitter valuediffers depending on the pulse width, the hatched region that is testeddiffers depending on the pulse width, as represented in the matrix imageshown in FIG. 29.

When the pulse width W4 is a pole, the pulse width W4 and a power P3with which the jitter value is minimized for the pulse width W4 are usedas a recording condition 104. As described above, by detecting a pole ofthe minimum jitter value in addition to the procedure of the exampleshown in FIG. 21, the test region can be extended in the direction ofpulse width by a small number of times of testing.

FIG. 30 is a schematic diagram showing an example where the test regionextends up to a point where a pole of minimum jitter value is obtained,in addition to the procedure of the example shown in FIG. 26. In theexample shown in FIG. 30, in addition to the procedure of the exampleshown in FIG. 26, power is changed and a pole of minimum jitter valuedetermined for each power value is used as a recording condition. Inthis example, the power value is sequentially changed as P1, P2, . . . ,and the procedure of the example shown in FIG. 26 is executed for eachof the power values. While comparing the minimum jitter values therebyobtained, this step is repeated until a power P4 with which the jittervalue is minimized is identified.

The pole of minimum jitter value can be identified by examining theamount of change between values at adjacent sample points. Thus, whenthe power P4 is a pole, test recording is carried out up to W5, which isimmediately subsequent to W4. Since the minimum jitter value differsdepending on the power value, the hatched region that is tested differsdepending on the power value, as represented in the matrix image shownin FIG. 30.

When the power value P4 is a pole, the power value P4 and a pulse widthW2 with which the jitter value is minimized for the power value P4 areused as a recording condition 104. As described above, by detecting apole of the minimum jitter value in addition to the procedure of theexample shown in FIG. 26, the test region can be extended in thedirection of pulse width by a small number of times of testing.

As described above, according to this embodiment, a power value and/or apulse range used in test recording are determined based on testing ofrecording characteristics, so that a more suitable recording conditioncan be determined by a smaller number of times of testing.

Preferably, recording characteristics are tested under a recordingenvironment that is similar to an actual recording environment in viewof medium characteristics, drive characteristics, and matchingtherebetween, determining a test condition based on the result oftesting.

Instead of changing the number of times of testing, the test region maybe shifted in accordance with the result of testing of recordingcharacteristics. For example, the following schemes may be employed whenrecording characteristics are predicted to have the same sensitivity,lower sensitivity, and higher sensitivity, respectively.

(1) When the Sensitivity of the Recording Medium is Substantially theSame as the Sensitivity of the Reference Medium

It is determined that the reference recording condition used for theprediction is close to an optimal condition. Thus, the power value andpulse width are extended by predetermined amounts with respect to thereference recording condition, and the resulting region is used as atest region. For example, when the reference recording condition is apower P and a pulse width W, the test region for the power value is P+5mW, and the test region for the pulse width is W ±0.2 T.

(2) When the Sensitivity of the Recording Medium is Lower than theSensitivity of the Reference Medium

It is determined that an optimal value for the recording medium requiresmore heat than an optimal value for the reference medium. Thus, the testregion is shifted to the side of high power and wide pulse width. Forexample, when the reference recording condition is a power P and a pulsewidth W, the test region for the power value is P to P+10 mW, and thetest region for the pulse width is W to W+0.4 T.

(3) When the Sensitivity of the Recording Medium is Higher than theSensitivity of the Reference Medium

It is determined that an optimal value for the recording medium requiresless heat than an optimal value for the reference medium. Thus, the testregion is shifted to the side of low power and narrow pulse width. Forexample, when the reference recording condition is a power P and a pulsewidth W, the test region for the power value is P−10 mW to P, and thetest region for the pulse width is W−0.4 T to W.

That is, in the example described above, with respect to the power P andthe pulse width W, a region defined by a power range of 10 mW and apulse range of 0.4 is shifted in accordance with recordingcharacteristics so that a more suitable recording condition will beobtained. The test region may be determined based on the eight patternsshown in FIG. 14 and described earlier.

Alternatively, the number of times of testing may be changed instead ofchanging the test range.

According to the embodiment, it is possible to find, by a smaller numberof times of testing, a recording condition suitable for a combination ofmedium and drive that are actually used. Thus, application to high-speedrecording or high-density recording, which is considerably affected bythe effect of variation in characteristics of media or drives, isexpected.

1. A recording method for recording information onto an opticalrecording medium, whose identification information is unknown, with arecording condition determined based on a result of test recordingcarried out by irradiating pulsed laser beams onto the medium, whereinthe test recording is carried out by changing the power and pulse widthof the laser beams in a stepwise manner, and a range of changing thepower and pulse width is determined based on a result of checkingrecording characteristics prior to the test recording.
 2. The recordingmethod according to claim 1, wherein the test recording is carried outby changing a pulse width in a stepwise manner and changing the power ina stepwise manner for each value of the pulse width changed.
 3. Therecording method according to claim 1, wherein the recordingcharacteristics are checked by carrying out test recording on theoptical recording medium by a plurality of predetermined referenceconditions and detecting a result of reproduced characteristics.
 4. Therecording method according to claim 1, wherein the test recording iscarried out by changing a power of the laser beams in a stepwise mannerand changing the pulse width in a stepwise manner for each value of thepower changed.
 5. An optical drive comprising: a laser light source; alaser light source controller coupled to said laser light source; and amemory storing information for use by said laser light source controllerin controlling said laser light source, wherein said informationcomprises a set of predefined laser light source test conditions, andwherein said optical drive is configured to, when working with anoptical recording medium whose identification information is unknown,define a second set of additional test recording conditions based on theresults of test recordings performed with said set of predefined laserlight source test conditions, wherein the test recording is carried outby changing the power and pulse width of the laser beams in a stepwisemanner, and a range of changing the power and pulse width is determinedbased on said set of predefined laser light source test conditions. 6.The optical drive of claim 5, wherein said optical drive is furtherconfigured to define a data recording condition based at least in parton test results from said additional test recording conditions.
 7. Anoptical drive comprising: a laser light source; means for recording testdata on an optical medium using a first defined set of test conditionscharacterized by one or more different laser pulse widths, laser pulsepowers, or both; means for making a first determination of recordingcharacteristics at said first predefined set of test conditions; meansfor defining a range of different laser pulse powers, laser pulsewidths, or both, based at least in part on said first determination;means for recording test data on said media using a second set of testconditions within said defined range of pulse powers, pulse widths, orboth; means for making a second determination of recordingcharacteristics at a plurality of said test conditions within saiddefined range; and means for defining a recording condition forrecording information onto said optical recording medium based at leastin part on said second determination.